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Covariant local field theory equations following from the relativistic canonical quantum mechanics of arbitrary spin
arXiv
Authors: Volodimir Simulik
Year
2014
Paper ID
47946
Status
Preprint
Abstract Read
~2 min
Abstract Words
124
Citations
N/A
Abstract
The new relativistic equations of motion for the particles with spin s=1, s=3/2, s=2 and nonzero mass have been introduced. The description of the relativistic canonical quantum mechanics of the arbitrary mass and spin has been given. The link between the relativistic canonical quantum mechanics of the arbitrary spin and the covariant local field theory has been found. The manifestly covariant field equations that follow from the quantum mechanical equations, have been considered. The covariant local field theory equations for spin s=(1,1) particle-antiparticle doublet, spin s=(1,0,1,0) particle-antiparticle multiplet, spin s=(3/2,3/2) particle-antiparticle doublet, spin s=(2,2) particle-antiparticle doublet, spin s=(2,0,2,0) particle-antiparticle multiplet and spin s=(2,1,2,1) particle-antiparticle multiplet have been introduced. The Maxwell-like equations for the boson with spin s=1 and m>0 have been introduced as well.
Why This Paper Matters
- This paper contributes to the Quantum Simulation research area in the Quantum Articles archive.
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- The new relativistic equations of motion for the particles with spin s=1, s=3/2, s=2 and nonzero mass have been introduced.
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